Energy saving stove water heater

ABSTRACT

The energy saving stove water heater includes a heat collecting body, with a tubular shape, having a water chamber surrounding with a heat source of the cooking stove, a water pipeline operatively communicating with the water chamber, and a top opening aligning with the heat source. Therefore, when a cooking tool supports on the heat collecting body at the top opening thereof, the heat source of the cooking stove is arranged to generate relatively high heat energy thermally transferring not only towards the cooking tool at the top opening but also towards the water chamber to heat up the water therewithin.

CROSS REFERENCE OF RELATED APPLICATION

This is a Continuation-In-Part application of a non-provisionalapplication having an application Ser. No. 12/310,789, and a filing dateof Mar. 5, 2009.

BACKGROUND OF THE PRESENT INVENTION

1. Field of Invention

This present invention relates to a water heater use in cooking stove,and more particularly to an energy saving stove water heater which iscapable of heating up water by means of the cooking stove.

2. Description of Related Arts

Nowadays, many people like to go out and eat because they don't havetime to prepare the food cook and to clean up the dishes after the meal.Therefore, more and more food restaurants are provided on the market. Inorder to provide those foods, those companies and restaurants need tofind proper appliance to assist them to cook. The kitchen in thetraditional restaurant usually comprises one or more cooking stoves andwater heaters. The cooking stove is used for providing heat to cook thefood. Meanwhile, the water heater is used for providing hot water.

However, the boundary wall of the stove cavity of conventional cookingstove used in family or restaurant is constructed with fireproof bricks.When cooking the food, the cooking stove usually generates huge amountof heat. Once the temperature of flame is too high, the fireproof brickof the cooking stove will be overheated and broken very easily. As aresult, the cooking stove is needed to maintained, repaired, or replacedfrequency. In addition, such stove cavity structure of the traditionalcooking stove can't efficiently utilize the excessive heat duringoperation. Therefore, it is a waste of thermal.

On the other hand, as everyone knows, the water heater is essentialequipment in restaurants not only providing hot water, hot soups ordrinks for their customers, but also forming a cooking apparatus to cookthe food. Therefore, people have invented various kinds of heater toheat up water and keep the water at a predetermined temperature. Thesize of the water heater is usually huge to fulfill the hot water demandfor the restaurant.

In order to heat up the water from room temperature to around 100° C.,the water heater has to consume huge amount of energy, such as gas orelectric. On the other hand, since the water conducts and radiates itsheat, the water temperature is kept decreasing at the same time. Thewater heater not only needs to heat water at high temperature, but alsoneeds to keep it warm. For example, if the user wants to heat and keep100 gallons of water at 100° C. for 24 hours, 50 W of power is theminimum electrical energy to be consumed. Not to mention if the waterheater is not an energy saving device, it consumes more energy tomaintain water at high temperature. To sum up, the heat output from thecooking stove and the energy transform and heat input for the waterheater at the same room are a big waste of thermal energy.

SUMMARY OF THE PRESENT INVENTION

The major object of the present invention is to provide an energy savingstove water heater, wherein the heat source of the cooking stove isarranged to generate relatively high heat energy thermally transferringnot only towards the cooking tool at the top opening but also towardsthe water chamber to heat up the water therewithin. It fully utilizesthe heat generated by a cooking stove for heating up the water in thewater tank so as to save energy, and protect the environment.Furthermore, the energy saving hydrant can protect the fireproof brickof the cooking stove from being overheated or burnt by the heat.

Another object of the present invention is to provide an energy savingstove water heater, which is designed to assure its operation safety.

Another object of the present invention is to provide an energy savingstove water heater, wherein the energy saving stove water heatercombines the cooking stove and water heater into a unity in such amanner that the volume of the whole appliance is much smaller and thematerial cost of the appliance is much lower either.

Another object of the present invention is to provide an energy savingstove water heater, which has a simple structure and is convenient forset up and use. Also, it can achieve the goal of reducing exhaust andsaving energy.

The energy saving stove water heater is capable of heating up water byfully utilizing the excessive heat from the cooking stove such thatthere is no need to consume any other energy to have hot water to saveenergy. In addition, the independent water heater has a compactstructure that is easier for set up and usage.

Accordingly, in order to accomplish the above object, the presentinvention provides an energy saving stove water heater for heating waterwith a cooking stove which comprise a heat collecting body, with atubular shape, having a water chamber surrounding with a heat source ofthe cooking stove, and a water pipeline operatively communicating withthe water chamber. The heat collecting body further has a top openingaligning with the heat source and arranged in such a manner that when acooking tool supports on the heat collecting body at the top openingthereof, the heat source of the cooking stove is arranged to generaterelatively high heat energy thermally transferring not only towards thecooking tool at the top opening but also towards the water chamber toheat up the water therewithin.

These and other objectives, features, and advantages of the presentinvention will become apparent from the following detailed description,the accompanying drawings, and the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an energy saving stove water heateraccording to a preferred embodiment of the present invention.

FIG. 2 is a sectional view of the energy saving stove water heateraccording to the above preferred embodiment of the present invention.

FIG. 3 is a sectional view of the energy saving stove water heateraccording to the second preferred embodiment of the present invention.

FIG. 4 is a sectional view of the energy saving stove water heateraccording to the third preferred embodiment of the present invention.

FIG. 5 is a sectional view of the energy saving stove water heateraccording to the fourth preferred embodiment of the present invention.

FIG. 6 is a perspective view of an energy saving stove water heateraccording to a fifth preferred embodiment of the present invention.

FIG. 7 is a side sectional view of the energy saving stove water heateraccording to the above fifth preferred embodiment of the presentinvention.

FIG. 8 is a top sectional view of the energy saving stove water heateraccording to the above fifth preferred embodiment of the presentinvention.

FIG. 9 illustrates an alternative mode of the energy saving stove waterheater according to the above fifth preferred embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIGS. 1 to 2 of the drawing, an energy saving stove waterheater according to a preferred embodiment of the present invention isillustrated, which comprises a water tank communicatively equipped witha cooking stove. The energy saving stove water heater is constructed byan inner tank body 1, an outer tank body 2, a top panel 3, and a bottompanel 4. The inner tank body 1 and the outer tank body 2 define aring-shape sealed water chamber 5 therebetween. The top panel 3 and thebottom panel 4 are connected on to a top side and a bottom side of thewater chamber 5 respectively so as to sealedly enclose the water chamber5 to form the water tank. The inner and outer tank bodies 1, 2 areprovided with a channel 6 extending through the water chamber 5 fordisposing the fuel line. The outer tank body 2 further has a water inlet7 and a water outlet 8.

In order to prevent the incoming cool water from the water inlet 7 fromimmediately exiting at the water outlet 8, an isolated wall 9 is builtbetween the water inlet 7 and the water outlet 8 in the water chamber 5for separating incoming cool water and the exiting heated water withinthe water chamber 5.

For security and safety purpose, a safety valve 10 is installed to theouter tank body 2. The safety valve is communicated with the waterchamber 5 for releasing the internal pressure and steam within the waterchamber 5 while the water being heated up therein.

The energy saving stove water heater further comprises an electricheater 11 installed near the water outlet 8 within the water chamber 5for generating electrical heat to heat up the water in the water chamber5, wherein when the temperature of water is detected lower than theusage requirement, the electric heater 11 is switched to heat up thewater to be exited through the water outlet 8 so as to ensure thetemperature of the water supply from the stove water heater of thepresent invention.

As a reasonable design, the inner and outer tank bodies 1, 2 areprovided with a ventilation channel 12 extending through the waterchamber 5, wherein the ventilation channel 12 can be extended to thebottom panel 4 in a vertical direction to form a groove to make a detourwith the exhaust line of the stove.

In view of above, a stove can be installed inside the cavity surroundedby the inner tank body 1 while the fuel pipe of the stove extendsthrough the channel 6 and the exhaust line passes through theventilation channel 12, not shown in FIGURES. In other words, theboundary bricks of the traditional stove are replaced by the stove waterheater of the present invention as shown in FIGS. 1 to 8 to use theexcessive heat generated from the stove to heat up the water flown inthe water chamber 5 of the stove water heater of the present invention.

Referring to FIG. 3 of the drawing, a second preferred embodiment of thepresent invention is illustrated, wherein the difference between thesecond preferred embodiment and the above preferred embodiment is thatthe cross section of the outer tank body 2 is in circular shape insteadof the rectangular shape as shown in FIGS. 1 to 2.

Referring to FIG. 4 of the drawing, a third preferred embodiment of thepresent invention is illustrated, wherein the difference between thethird preferred embodiment and the above preferred embodiment is thatthe cross section of the inner tank body 2 in the third preferredembodiment is in hexagonal shape.

According to the fourth embodiment as shown in FIG. 5, the energy savingstove water heater of the present invention can be constructed by a lefthalf body 13 and a right half body 14. The left half body 13 and theright half body 14 has a communicating tube 15 to connect with eachother, wherein each of the left and right half body 13, 14 is providedwith the water inlet 7 and the water outlet 8 respectively.

It is worth to mentioning that a cross section of the inner tank body 1of the energy saving stove water heating is in circular shape.

As shown in FIGS. 6 to 8, an energy saving stove water heater of a fifthembodiment illustrates an alternative mode of the first embodiment ofthe present invention.

According to the fifth embodiment, the energy saving stove water heater,which is incorporating with a cooking stove 10′, comprises a heatcollecting body, with a tubular shape, having a water chamber 20′surrounding with a heat source 11′ of the cooking stove 10′, and a waterpipeline 30′ operatively communicating with the water chamber 20′. Theheat collecting body further has a fuel line channel 6′ extendingthrough the water chamber 20′ for disposing the fuel line.

The heat collecting body further has a top opening 40′ aligning with theheat source 11′ and arranged in such a manner that when a cooking tool12′ supports on the heat collecting body at the top opening 40′ thereof,the heat source 11′ of the cooking stove 10′ is arranged to generaterelatively high heat energy thermally transferring not only towards saidcooking tool 12′ at the top opening 40′ but also towards the waterchamber 20′ to heat up the water therewithin.

In other words, the heat source 11′, such as flame, of the energy savingstove water heater adapts for not only perpendicular generating heat tothe cooking stove 10′ but also providing heat to the water heater duringoperation. Therefore, the energy saving stove water heater fullyutilizes the heat generated by the heat source 11′ of the cooking stove10′ for heating up the water in the water chamber 20′ so as to saveenergy, and protect the environment. Accordingly, the cooking stove 10′can electric stove, or gas stove in which they are commonly utilized inthe kitchen. Preferably, the gas-type cooking stove 10′ is preferredbecause the heat source 11′ can generate relative high heat energy atfew hundred degrees Celsius.

As shown in FIGS. 7 and 8, the heat collecting body comprises an innertank body 21′, an outer tank body 22′, a top panel 23′, and a bottompanel 24′. The inner tank body 21′ is spacedly supported within theouter tank body 22′ to define the sealed water chamber 20′ therebetween.The top panel 23′ and the bottom panel 24′ are connected on to a topside and a bottom side of the water chamber 20′ respectively so as tosealedly enclose the water chamber 20′ to form the water tank. The topopening 40′ is formed at the top panel 23′ of the heat collecting body.In addition, a heat cavity 25′ is formed within the inner tank body 21′to align with the top opening 40′ for retaining the heat source 11′within the heat chamber 25′. Accordingly, the fuel line channel 6′ isextended from the outer tank body 22′ through the inner tank body 21′ tocommunicate with the heat cavity 25′. In other words, the heat source11′ is disposed within the heat cavity 25′ at a position that the fuelline of cooking stove 10′ is extended from the heat source 11′ to thefuel source through the fuel line channel 6′.

Accordingly, the outer tank body 22′ is made of thermally insulatedmaterial for effectively maintaining the heat energy to heat up thewater within the water chamber 20′, while the inner tank body 21′ ismade of thermally conductive material for effectively conducting theheat energy from the heat chamber 25′ to the water chamber 20′.

The water pipeline 30′ comprises a water inlet 31′ operatively extendedfrom the heat collecting body for controlling an incoming cool waterinto the water chamber 20′ and a water outlet 32′ operatively extendedfrom the heat collecting body for exiting heated water from the waterchamber 20′. Accordingly, the water inlet 31′ and the water outlet 32′are spacedly extended from the outer tank body 22′. The incoming coolwater enters into the water chamber 20′ through the water inlet 31′.After the water is heated up within the water chamber 20′, the heatedwater will exit the water chamber 20′ through the water outlet 32′.

Accordingly, the user is able to adjustably control the flow rate of thewater through the water chamber 20′ via the water inlet 31′. When a lotof hot water is needed, especially during the peak-cooking hours of theday, the user is able to increase the flow rate of water via the waterinlet 31′ to let more water entering into the water chamber 20′. It isworth mentioning that during the peak-cooking hours, the heat source 11′of the cooking stove 10′ will be fully operated. Therefore, even thoughthe flow rate of water is increased, the heat source 11′ is adapted toeffectively heat up the water through the heat collecting body.Likewise, the user is able to reduce the flow rate of water via thewater inlet 31′ to reduce the amount of water entering into the waterchamber 20′. During the non-peak-cooking hours of the day, the heatsource 11′ of the cooking stove 10′ may not be fully operated.Therefore, the water with the reduced flow rate will have enough time tobe heated up by the heat source 11′ of the cooking stove 10′.

As shown in FIG. 7, the heat collecting body further comprises anisolated wall 26′ supported within the water chamber 20′ at a positionbetween the water inlet 31′ and the water outlet 32′ for separating theincoming cool water with the exiting heated water in the water chamber20′ so as to ensure the water being effectively heated up within thewater chamber 20′. Accordingly, the isolated wall 26′ is extendedbetween the wall of the inner tank body 21′ and the wall of the outertank body 22′.

As shown in FIG. 7, the water inlet 31′ and the water outlet 32′ arespacedly extended from the rear wall of the outer tank body 22′.Therefore, the incoming cool water entering into the water chamber 20′at the water inlet 31′ may directly exit the water chamber 20′ at thewater outlet 32′. In order to prevent the incoming cool water from thewater inlet 31′ from immediately exiting at the water outlet 32′, theisolated wall 26′ is built between the water inlet 31′ and the wateroutlet 32′ in the water chamber 20′ for separating incoming cool waterand the exiting heated water within the water chamber 20′. In otherwords, the incoming cool water must flow around the water chamber 20′from the water inlet 31′ to the water outlet 32′ such that the heat fromthe heat source 11′ will have enough time to heat up the water withinthe water chamber 20′.

The energy saving stove water further comprises a safety valve 50′provided at the heat collecting body to operatively communicate with thewater chamber 20′ for releasing internal pressure and steam within thewater chamber 20′ whiling heating up the water therewithin. Accordingly,the internal pressure of the heat collecting body gradually increaseswhen the water is heated up within the water chamber 20′. Therefore, thesafety valve 50′ will be automatically actuated to release excessiveinternal pressure for preventing the expansion or explosion of the heatcollecting body.

It is worth to mention that the energy saving stove water heater furthercomprises a supplemental heater 61′ supported within the water chamber20′ for generating additional heat energy therewithin for heating up thewater passing through the water chamber 20′, and a water temperaturesensor 62′ operatively linked to the supplemental heater 61′ to activatethe supplemental heater 61′ when the water temperature of the water isbelow a preset temperature. When the water passes into the water chamber20′ through the water inlet 31′, the water is heated by the heat withinthe heat cavity 25′. In other words, the water chamber 20′ and the heatcavity 25′ are thermally communicated with each other for heat exchangeso as to heat up the water within the water chamber 20′.

The water temperature sensor 62′ is adapted to detect the watertemperature of the water chamber 20′. When the water is not heated upwithin the water chamber 20′ by the heat source 11′ at a predeterminedtemperature, the water temperature sensor 62′ will automaticallyactivate the supplemental heater 61′ for heat generation to heat up thewater until the water temperature of the water within the water chamber20′ reaches the predetermined temperature, so as to ensure the hot waterflowing out at the water outlet 32′. Accordingly, the water should beheated up at 95° C.

For example, the water temperature sensor 62′, which is connectedbetween the supplemental heater 61′ and the water outlet 32′, comprisesa preset temperature controller within the water temperature sensor 62′with 80° C. for turning on and cutting off the power supply of thesupplemental heater 61′. The temperature sensor 62′ monitors thetemperature of water in the water chamber 20′ in real-time. When thetemperature of water is lower than the preset temperature 80° C., thesupplemental heater 61′ turns on the power supply of the supplementalheater 61′ to heat up water till 95° C. On the contrary, once thetemperature of water is higher than the preset temperature 95° C., thesupplemental heater 61′ automatically deactivates the power switch ofthe supplemental heater 61′. Moreover, the user is able to set thesaving energy mode other than the office hour to turns off thesupplemental heater 61′ for save more energy.

On the other hand, according to the energy conservation law, when thewater temperature within the water chamber 20′ is higher than the presettemperature 95° C., the supplemental heater 61′ is automatically shutdown. More water coming in and more water coming out will lead to thewater temperature drop down dramatically. Therefore, the energy consumedby the supplemental heater 61′ will be substantially reduced.

The heat collecting body further has a ventilation channel 63′ extendingthrough the water chamber 20′ for forming a detour with exhaust line ofthe cooking stove 10′, wherein the ventilation channel 63′ allows theexcessive heat exiting from the heat cavity 25′ for preventing the heatcollecting body from being overheated.

Accordingly, the present invention further provides a method for heatingwater with the cooking stove 10′ which comprises the following steps.

(1) Position the heat source 11′ of the cooking stove 10′ within theheat cavity 25′ of heat collecting body at a position that the waterchamber 20′ of the heat collecting body is surrounding with the heatsource 11′.

(2) Guide the water flow through the water chamber 20′ via the waterpipeline 30′ that the water enters into the water chamber 20′ at thewater inlet 31′ and exits the water chamber 20′ at the water outlet 32′.

(3) Operate the heat source 11′ to generate relatively high heat energy.Therefore, when the cooking tool 12′ supports on the heat collectingbody at a top opening 40′ thereof to align with the heat source 11′, theheat energy thermally transfers not only towards cooking tool 12′ at thetop opening 40′ but also towards the water chamber 20′ to heat up thewater therewithin.

The step (2) further comprises a step of separating the incoming coolwater with the exiting heated water in the water chamber 20′ via theisolated wall 26′ extended between the inner and outer tank bodies 21′,22′ within the water chamber 20′ at a position between the water inlet31′ and the water outlet 32′.

The method further comprises a step of releasing the internal pressureand steam within the water chamber 20′ whiling heating up said watertherewithin via the safety valve 50′.

The method comprises a step of generating additional heat energy withinthe water chamber 20′ via the supplemental heater 61′ for heating up thewater passing through the water chamber 20′ when the water temperatureof the water is below a preset temperature.

FIG. 9 illustrates an alternative mode of the energy saving stove waterheater which comprises a heat collecting body, with a tubular shape,having a water chamber 20A surrounding with a heat source 11A of thecooking stove 10A, and a water pipeline 30A operatively communicatingwith the water chamber 20A. The heat collecting body further has a fuelline channel 6A extending through the water chamber 20A for disposingthe fuel line.

The heat collecting body further has a top opening 40A aligning with theheat source 11A and arranged in such a manner that when a cooking tool12′ supports on the heat collecting body at the top opening 40A thereof,the heat source 11A of the cooking stove 10A is arranged to generaterelatively high heat energy thermally transferring not only towards saidcooking tool 12′ at the top opening 40A but also towards the waterchamber 20A to heat up the water therewithin.

The heat collecting body comprises an inner tank body 21A and an outertank body 22A, wherein the inner tank body 21A is spacedly supportedwithin the outer tank body 22A to define the sealed water chamber 20Atherebetween. In addition, a heat cavity 25A is formed within the innertank body 21A to align with the top opening 40A for retaining the heatsource 11A within the heat chamber 25A. Accordingly, the outer tank body22A is made of thermally insulated material for effectively maintainingthe heat energy to heat up the water within the water chamber 20A, whilethe inner tank body 21A is made of thermally conductive material foreffectively conducting the heat energy from the heat chamber 25A to thewater chamber 20A.

The water pipeline 30A comprises a water inlet 31A operatively extendedfrom the heat collecting body for controlling an incoming cool waterinto the water chamber 20A and a water outlet 32A operatively extendedfrom the heat collecting body for exiting heated water from the waterchamber 20A. Accordingly, the water inlet 31A and the water outlet 32Aare spacedly extended from the outer tank body 22A.

The heat collecting body further comprises an isolated wall 26Asupported within the water chamber 20A at a position between the waterinlet 31A and the water outlet 32A for separating the incoming coolwater with the exiting heated water in the water chamber 20A so as toensure the water being effectively heated up within the water chamber20A. Accordingly, the isolated wall 26A is extended between the wall ofthe inner tank body 21A and the wall of the outer tank body 22A.

The energy saving stove water further comprises a safety valve 50Aprovided at the heat collecting body to operatively communicate with thewater chamber 20A for releasing internal pressure and steam within thewater chamber 20A whiling heating up the water therewithin. Accordingly,the internal pressure of the heat collecting body gradually increaseswhen the water is heated up within the water chamber 20A.

The energy saving stove water heater further comprises a supplementalheater 61A supported within the water chamber 20A for generatingadditional heat energy therewithin for heating up the water passingthrough the water chamber 20A, and a water temperature sensor 62Aoperatively linked to the supplemental heater 61A to activate thesupplemental heater 61A when the water temperature of the water is belowa preset temperature. When the water passes into the water chamber 20Athrough the water inlet 31A, the water is heated by the heat within theheat cavity 25A. In other words, the water chamber 20A and the heatcavity 25A are thermally communicated with each other for heat exchangeso as to heat up the water within the water chamber 20A.

Accordingly, the alternative mode of the energy saving stove waterheater has the same structural configuration of the fifth embodiment.The differences between the alternative mode and the fifth embodimentare that the shape of the heat collecting body.

As shown in FIG. 7, the outer tank body 22′ of the fifth embodiment hasa rectangular shape, wherein the outer tank body 22A of the alternativemode has a circular shape.

In addition, the heat collecting body further comprises a plurality ofheat conductive elements 64A, embodied as fin structure, inwardly andradially extended from the inner tank body 21A within the heat cavity25A, wherein the heat conductive elements 64A are made of heatconductive material and are adapted to effectively transmit the heatwithin the heat cavity 25A to the water chamber 20A through the innertank body 21A. Therefore, the water within the water chamber 20A can beeffectively heated up by the heat of the heat source 11A.

It is worth to mention that since the heat within the heat cavity 25Acan be effectively transmitted to the water chamber 20A via the heatconductive elements 64A, the ventilation channel 63′ as shown in FIG. 7can be omitted.

One skilled in the art will understand that the embodiment of thepresent invention as shown in the drawings and described above isexemplary only and not intended to be limiting.

It will thus be seen that the objects of the present invention have beenfully and effectively accomplished. The embodiments have been shown anddescribed for the purposes of illustrating the functional and structuralprinciples of the present invention and is subject to change withoutdeparture from such principles. Therefore, this invention includes allmodifications encompassed within the spirit and scope of the followingclaims.

1. An energy saving stove water heater for heating water with a cooking stove, comprising a heat collecting body, with a tubular shape, having a water chamber surrounding with a heat source of said cooking stove, a water pipeline operatively communicating with said water chamber, and a top opening aligning with said heat source and arranged in such a manner that when a cooking tool supports on said heat collecting body at said top opening thereof, said heat source of said cooking stove is arranged to generate relatively high heat energy thermally transferring not only towards said cooking tool at said top opening but also towards said water chamber to heat up said water therewithin.
 2. The energy saving stove water heater, as recited in claim 1, wherein said heat collecting body comprises an outer tank body and an inner tank body spacedly supported within said outer tank body to define said water chamber between said outer tank body and said inner tank body and to form a heat chamber within said inner tank body for retaining said heat source within said heat chamber.
 3. The energy saving stove water heater, as recited in claim 2, wherein said outer tank body is made of thermally insulated material for effectively maintaining said heat energy to heat up said water within said water chamber, while said inner tank body is made of thermally conductive material for effectively conducting said heat energy from said heat chamber to said water chamber.
 4. The energy saving stove water heater, as recited in claim 2, wherein said water pipeline comprises a water inlet operatively extended from said heat collecting body for controlling an incoming cool water into said water chamber and a water outlet operatively extended from said heat collecting body for exiting heated water from said water chamber.
 5. The energy saving stove water heater, as recited in claim 3, wherein said water pipeline comprises a water inlet operatively extended from said heat collecting body for controlling an incoming cool water into said water chamber and a water outlet operatively extended from said heat collecting body for exiting heated water from said water chamber.
 6. The energy saving stove water heater, as recited in claim 4, wherein said heat collecting body further comprises an isolated wall extended between said inner and outer tank bodies within said water chamber at a position between said water inlet and said water outlet for separating said incoming cool water with said exiting heated water in said water chamber so as to ensure said water being effectively heated up within said water chamber.
 7. The energy saving stove water heater, as recited in claim 5, wherein said heat collecting body further comprises an isolated wall extended between said inner and outer tank bodies within said water chamber at a position between said water inlet and said water outlet for separating said incoming cool water with said exiting heated water in said water chamber so as to ensure said water being effectively heated up within said water chamber.
 8. The energy saving stove water heater, as recited in claim 1, further comprising a safety valve provided at said heat collecting body to operatively communicate with said water chamber for releasing internal pressure and steam within said water chamber whiling heating up said water therewithin.
 9. The energy saving stove water heater, as recited in claim 7, further comprising a safety valve provided at said heat collecting body to operatively communicate with said water chamber for releasing internal pressure and steam within said water chamber whiling heating up said water therewithin.
 10. The energy saving stove water heater, as recited in claim 1, further comprising a supplemental heater supported within said water chamber for generating additional heat energy therewithin for heating up said water passing through said water chamber, and a water temperature sensor operatively linked to said supplemental heater to activate said supplemental heater when said water temperature of said water is below a preset temperature.
 11. The energy saving stove water heater, as recited in claim 9, further comprising a supplemental heater supported within said water chamber for generating additional heat energy therewithin for heating up said water passing through said water chamber, and a water temperature sensor operatively linked to said supplemental heater to activate said supplemental heater when said water temperature of said water is below a preset temperature.
 12. The energy saving stove water heater, as recited in claim 11, wherein said heat collecting body further has a ventilation channel extending through said water chamber for forming a detour with exhaust line of said cooking stove.
 13. The energy saving stove water heater, as recited in claim 11, wherein said heat collecting body further comprises a plurality of heat conductive elements inwardly and radially extended from said inner tank body within said heat cavity, wherein said heat conductive elements are made of heat conductive material and are adapted to effectively transmit said heat within said heat cavity to said water chamber through said inner tank body.
 14. A method of heating water with a cooking stove, comprising the steps of: (a) positioning a heat source of said cooking stove in a heat collecting body at a position that a water chamber of said heat collecting body is surrounding with said heat source; (b) guiding a water flow through said water chamber via a water pipeline; and (c) operating said heat source to generate relatively high heat energy, wherein when a cooking tool supports on said heat collecting body at a top opening thereof to align with said heat source, said heat energy thermally transfers not only towards said cooking tool at said top opening but also towards said water chamber to heat up said water therewithin.
 15. The method, as recited in claim 14, wherein said heat collecting body comprises an outer tank body and an inner tank body spacedly supported within said outer tank body to define said water chamber between said outer tank body and said inner tank body and to form a heat chamber within said inner tank body for retaining said heat source within said heat chamber.
 16. The method, as recited in claim 15, wherein said outer tank body is made of thermally insulated material for effectively maintaining said heat energy to heat up said water within said water chamber, while said inner tank body is made of thermally conductive material for effectively conducting said heat energy from said heat chamber to said water chamber.
 17. The method, as recited in claim 16, wherein the step (b) comprises the steps of controlling an incoming cool water into said water chamber via a water inlet and exiting heated water from said water chamber via a water outlet.
 18. The method, as recited in claim 17, wherein the step (b) further comprises a step of separating said incoming cool water with said exiting heated water in said water chamber via an isolated wall extended between said inner and outer tank bodies within said water chamber at a position between said water inlet and said water outlet.
 19. The method, as recited in claim 18, further comprising a step of releasing internal pressure and steam within said water chamber whiling heating up said water therewithin via a safety valve.
 20. The method, as recited in claim 18, further comprising a step of generating additional heat energy within said water chamber for heating up said water passing through said water chamber when a water temperature of said water is below a preset temperature. 